1 / 33

Supercritical and mixed regime flows

Supercritical and mixed regime flows. Background. Most open channel flows are above critical depth (subcritical flow with low velocities) In steep channels flows may be below critical depth (supercritical flow with high velocities)

adriel
Download Presentation

Supercritical and mixed regime flows

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Supercritical and mixed regime flows

  2. Background • Most open channel flows are above critical depth (subcritical flow with low velocities) • In steep channels flows may be below critical depth (supercritical flow with high velocities) • Energy considerations for an open channel govern whether the depth is above or below critical depth

  3. Energy in open channels • For a given discharge, there are two possible depths for a given energy, (except at minimum energy -critical depth) • For a given discharge, there must be some minimum energy for this flow to exist (this minimum occurs at critical depth) Total energy = WS Elev + aV2/2g Total energy = WS Elev + [aQ2/2g]/A2 A = f(depth) = f(WS Elev)

  4. Flow energy for a given discharge Critical Depth, yc Minimum energy

  5. Subcritical and Supercritical Flow Definition is based on velocity: y > yc V < Vc Subcritical y = yc V = Vc Critical y < yc V > Vc Supercritical

  6. Critical depth calculation • Energy Equation: E = Z + y + V2/2g = Z + y + (Q/A)2/2g • Energy is minimum at yc When E = Emin, dE/dy = 0 dE/dv = dZ/dy + dy/dy + (Q2/2g)2A-3dA/dy 0 = 0 + 1 + Q2/(gA3) dA/dy Since A = f(y), dA ≈ Tdy, dA/dy ≈ T • So at critical depth, Q2T/(gA3) = 1 or A3 /T = Q2/g

  7. The Froude number At critical depth: Q2T/(gA3) = 1 (Q/A)2/(g A/T) = 1 The right hand side of the equation is a dimensionless ratio (the Froude number squared) Q/A = V (the mean velocity) A/T = D (the hydraulic depth)

  8. Common form of the Froude number

  9. Wave speed in an open channel cwave Dy Y = flow depth In a rectangular channel y = A/T

  10. Velocity at yc = wave velocity

  11. Speed of disturbance in open channel Wave movement in subcritical flow • Vavg < Vc • Wave can move upstream and downstream Wave movement in supercritical flow • Vavg > Vc • Wave can move only downstream

  12. Flow Regime Types • Critical Flow Fr = 1 • Subcritical Flow Fr < 1 • Supercritical Flow Fr > 1

  13. Expansion and contraction losses • Expansion and contraction losses used for supercritical flow should be lower than those used for subcritical flow • The standard coefficients tend to overestimate the losses in supercritical flow • If there is no contraction or expansion you may want to set the coefficients equal to zero • Typical values for gradual transitions in natural channels: • Contraction -- 0.05 • Expansion -- 0.10

  14. “Controls” in open channel flow Location of a control • Critical depth at change in channel slope • Normal depth in a very long channel • Gate in channel How controls affect boundary conditions • Subcritical flow is subject to downstream BC • Supercritical flow is subject to upstream BC • Mixed flow regime requires both upstream and downstream BC

  15. Upstream BC Downstream BC Internal BC Mixed Flow

  16. Hydraulic jump • A hydraulic jump is a sudden dissipation of energy caused by a change from super-critical to sub-critical flow. • At the start of the jump, the flow height will begin to increase, and the velocity will slow creating an area of turbulence. • At the end of the jump, the flow height will level off again, and the fluid will continue flowing smoothly.

  17. Hydraulic jumps • Hydraulic jumps dissipate a large amount of energy in open channel flows. This makes hydraulic jumps very useful in dam and spillway designs. • Often special features are needed to make jumps occur at desired locations such as at the bottom of a spillway. • Increasing surface roughness, adding a baffle wall, or sloping the basin floor can all help force a hydraulic jump.

  18. Effect of the Froude number • The major parameter influencing a hydraulic jump is the Froude Number, Fr. • The best design range for the Froude number is 4.5 to 9.0. In this range, a well-balanced steady jump will occur with a large amount of energy dissipation. • A Froude number of 2.5 to 4.5 is the worst design range, as the jump in this range will create large waves that could cause structural damage.

  19. At a hydraulic jump • Balance in pressure and momentum • S Forces = ma Well-defined jump in laboratory Weak jump in field

  20. Controlled Hydraulic Jump

  21. Flow near critical?

  22. Roughness coefficients – steep streams Gravel bed streams

  23. High Velocity, Near Critical Flow RAS profile plot

  24. Critical Depth - Parabolic Method Water Surface Elevation 1 2 WScrit 3 Hmin Total Energy, H

  25. HEC-RAS Cross Sections Right overbank Left overbank High Flow n1 n3 n4 n2 A1 P1 A2 P2 A3 P3 Ach Pch Klob = K1 + K2 Krob = K3 Kch Low Flow

  26. Critical Depth - Slicing Method Water Surface Elevation Local minimum energy Top of bank or ineffective flow WScrit Hmin Total Energy H

  27. RAS Output Table with Multiple Critical Depths

  28. Critical Depth - Procedure • Program uses Parabolic method by default • This can be changed to the Slicing method • Program automatically switches to slicing method if any of the following occur: • Parabolic method fails to get answer within tolerance • Parabolic answer is at or near top of levee of ineffective flow area

  29. Junctions in Supercritical Flow • Supercritical flows with changes in boundary alignments are generally complicated by standing waves. • In tranquil flow, backwater effects are propagated upstream, tending to equalize the flow depths in the main and side channels. • However, backwater cannot be propagated upstream in rapid flow, and flow depths in the main and side channels cannot generally be expected to be equal.

  30. RAS junction analysis • Junctions for rapid flows and very small junction angles are designed assuming equal water-surface elevations in the side and main channels. • Model tests by the Corps on rapid-flow junctions have verified the use of the momentum equation for this purpose.  

  31. Air entrainment in high velocity streams • For channels with high flow velocity the water surface may be slightly higher than the computed value due to air entrainment • For river flows this is usually not important • For chutes and concrete channels with Froude numbers greater than 1.6, this can be significant • The water surface with air entrainment is computed by RAS and can be displayed in the output tables • For 1.6<Fr<8.2, Da=0.906D(e0.061Fr) Da=depth with air entrainment D = computed depth Fr = Froude number e = 2.718282 (base of natural logs)

  32. Hydraulic jump in a closed conduit Use cross section with lid

  33. Cross section with lid • Grey area is lid • Lid must extend above HGL (what RAS considers as water surface)

More Related